Treatment of Textile Wastewater Using Advanced Oxidation Processes—A Critical Review

Textile manufacturing is a multi-stage operation process that produces significant amounts of highly toxic wastewater. Given the size of the global textile market and its environmental impact, the development of effective, economical, and easy-to handle alternative treatment technologies for textile...
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Autor*in:	Yiqing Zhang [verfasserIn] Kashif Shaad [verfasserIn] Derek Vollmer [verfasserIn] Chi Ma [verfasserIn]

Format:	E-Artikel
Sprache:	Englisch

Erschienen:	2021

Schlagwörter:	textile wastewater advanced oxidation process electrical energy per order Fenton process

Übergeordnetes Werk:	In: Water - MDPI AG, 2010, 13(2021), 24, p 3515
Übergeordnetes Werk:	volume:13 ; year:2021 ; number:24, p 3515

Links:	Link aufrufen Link aufrufen Link aufrufen Journal toc

DOI / URN:	10.3390/w13243515

Katalog-ID:	DOAJ074086006

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520			\|a Textile manufacturing is a multi-stage operation process that produces significant amounts of highly toxic wastewater. Given the size of the global textile market and its environmental impact, the development of effective, economical, and easy-to handle alternative treatment technologies for textile wastewater is of significant interest. Based on the analysis of peer-reviewed publications over the last two decades, this paper provides a comprehensive review of advanced oxidation processes (AOPs) on textile wastewater treatment, including their performances, mechanisms, advantages, disadvantages, influencing factors, and electrical energy per order (E<sub<EO</sub<) requirements. Fenton-based AOPs show the lowest median E<sub<EO</sub< value of 0.98 kWh m<sup<−3</sup< order<sup<−1</sup<, followed by photochemical (3.20 kWh m<sup<−3</sup< order<sup<−1</sup<), ozonation (3.34 kWh m<sup<−3</sup< order<sup<−1</sup<), electrochemical (29.5 kWh m<sup<−3</sup< order<sup<−1</sup<), photocatalysis (91 kWh m<sup<−3</sup< order<sup<−1</sup<), and ultrasound (971.45 kWh m<sup<−3</sup< order<sup<−1</sup<). The Fenton process can treat textile effluent at the lowest possible cost due to the minimal energy input and low reagent cost, while Ultrasound-based AOPs show the lowest electrical efficiency due to the high energy consumption. Further, to explore the applicability of these methods, available results from a full-scale implementation of the enhanced Fenton technology at a textile mill wastewater treatment plant (WWTP) are discussed. The WWTP operates at an estimated cost of CNY ¥1.62 m<sup<−3</sup< (USD $0.23 m<sup<−3</sup<) with effluent meeting the China Grade I-A pollutant discharge standard for municipal WWTPs, indicating that the enhanced Fenton technology is efficient and cost-effective in industrial treatment for textile effluent.
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callnumber-first	T - Technology
author	Yiqing Zhang
spellingShingle	Yiqing Zhang misc TC1-978 misc TD201-500 misc textile wastewater misc advanced oxidation process misc electrical energy per order misc Fenton process misc Hydraulic engineering misc Water supply for domestic and industrial purposes Treatment of Textile Wastewater Using Advanced Oxidation Processes—A Critical Review
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title	Treatment of Textile Wastewater Using Advanced Oxidation Processes—A Critical Review
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title_full	Treatment of Textile Wastewater Using Advanced Oxidation Processes—A Critical Review
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title_sort	treatment of textile wastewater using advanced oxidation processes—a critical review
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title_auth	Treatment of Textile Wastewater Using Advanced Oxidation Processes—A Critical Review
abstract	Textile manufacturing is a multi-stage operation process that produces significant amounts of highly toxic wastewater. Given the size of the global textile market and its environmental impact, the development of effective, economical, and easy-to handle alternative treatment technologies for textile wastewater is of significant interest. Based on the analysis of peer-reviewed publications over the last two decades, this paper provides a comprehensive review of advanced oxidation processes (AOPs) on textile wastewater treatment, including their performances, mechanisms, advantages, disadvantages, influencing factors, and electrical energy per order (E<sub<EO</sub<) requirements. Fenton-based AOPs show the lowest median E<sub<EO</sub< value of 0.98 kWh m<sup<−3</sup< order<sup<−1</sup<, followed by photochemical (3.20 kWh m<sup<−3</sup< order<sup<−1</sup<), ozonation (3.34 kWh m<sup<−3</sup< order<sup<−1</sup<), electrochemical (29.5 kWh m<sup<−3</sup< order<sup<−1</sup<), photocatalysis (91 kWh m<sup<−3</sup< order<sup<−1</sup<), and ultrasound (971.45 kWh m<sup<−3</sup< order<sup<−1</sup<). The Fenton process can treat textile effluent at the lowest possible cost due to the minimal energy input and low reagent cost, while Ultrasound-based AOPs show the lowest electrical efficiency due to the high energy consumption. Further, to explore the applicability of these methods, available results from a full-scale implementation of the enhanced Fenton technology at a textile mill wastewater treatment plant (WWTP) are discussed. The WWTP operates at an estimated cost of CNY ¥1.62 m<sup<−3</sup< (USD $0.23 m<sup<−3</sup<) with effluent meeting the China Grade I-A pollutant discharge standard for municipal WWTPs, indicating that the enhanced Fenton technology is efficient and cost-effective in industrial treatment for textile effluent.
abstractGer	Textile manufacturing is a multi-stage operation process that produces significant amounts of highly toxic wastewater. Given the size of the global textile market and its environmental impact, the development of effective, economical, and easy-to handle alternative treatment technologies for textile wastewater is of significant interest. Based on the analysis of peer-reviewed publications over the last two decades, this paper provides a comprehensive review of advanced oxidation processes (AOPs) on textile wastewater treatment, including their performances, mechanisms, advantages, disadvantages, influencing factors, and electrical energy per order (E<sub<EO</sub<) requirements. Fenton-based AOPs show the lowest median E<sub<EO</sub< value of 0.98 kWh m<sup<−3</sup< order<sup<−1</sup<, followed by photochemical (3.20 kWh m<sup<−3</sup< order<sup<−1</sup<), ozonation (3.34 kWh m<sup<−3</sup< order<sup<−1</sup<), electrochemical (29.5 kWh m<sup<−3</sup< order<sup<−1</sup<), photocatalysis (91 kWh m<sup<−3</sup< order<sup<−1</sup<), and ultrasound (971.45 kWh m<sup<−3</sup< order<sup<−1</sup<). The Fenton process can treat textile effluent at the lowest possible cost due to the minimal energy input and low reagent cost, while Ultrasound-based AOPs show the lowest electrical efficiency due to the high energy consumption. Further, to explore the applicability of these methods, available results from a full-scale implementation of the enhanced Fenton technology at a textile mill wastewater treatment plant (WWTP) are discussed. The WWTP operates at an estimated cost of CNY ¥1.62 m<sup<−3</sup< (USD $0.23 m<sup<−3</sup<) with effluent meeting the China Grade I-A pollutant discharge standard for municipal WWTPs, indicating that the enhanced Fenton technology is efficient and cost-effective in industrial treatment for textile effluent.
abstract_unstemmed	Textile manufacturing is a multi-stage operation process that produces significant amounts of highly toxic wastewater. Given the size of the global textile market and its environmental impact, the development of effective, economical, and easy-to handle alternative treatment technologies for textile wastewater is of significant interest. Based on the analysis of peer-reviewed publications over the last two decades, this paper provides a comprehensive review of advanced oxidation processes (AOPs) on textile wastewater treatment, including their performances, mechanisms, advantages, disadvantages, influencing factors, and electrical energy per order (E<sub<EO</sub<) requirements. Fenton-based AOPs show the lowest median E<sub<EO</sub< value of 0.98 kWh m<sup<−3</sup< order<sup<−1</sup<, followed by photochemical (3.20 kWh m<sup<−3</sup< order<sup<−1</sup<), ozonation (3.34 kWh m<sup<−3</sup< order<sup<−1</sup<), electrochemical (29.5 kWh m<sup<−3</sup< order<sup<−1</sup<), photocatalysis (91 kWh m<sup<−3</sup< order<sup<−1</sup<), and ultrasound (971.45 kWh m<sup<−3</sup< order<sup<−1</sup<). The Fenton process can treat textile effluent at the lowest possible cost due to the minimal energy input and low reagent cost, while Ultrasound-based AOPs show the lowest electrical efficiency due to the high energy consumption. Further, to explore the applicability of these methods, available results from a full-scale implementation of the enhanced Fenton technology at a textile mill wastewater treatment plant (WWTP) are discussed. The WWTP operates at an estimated cost of CNY ¥1.62 m<sup<−3</sup< (USD $0.23 m<sup<−3</sup<) with effluent meeting the China Grade I-A pollutant discharge standard for municipal WWTPs, indicating that the enhanced Fenton technology is efficient and cost-effective in industrial treatment for textile effluent.
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title_short	Treatment of Textile Wastewater Using Advanced Oxidation Processes—A Critical Review
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The Fenton process can treat textile effluent at the lowest possible cost due to the minimal energy input and low reagent cost, while Ultrasound-based AOPs show the lowest electrical efficiency due to the high energy consumption. Further, to explore the applicability of these methods, available results from a full-scale implementation of the enhanced Fenton technology at a textile mill wastewater treatment plant (WWTP) are discussed. The WWTP operates at an estimated cost of CNY ¥1.62 m<sup<−3</sup< (USD $0.23 m<sup<−3</sup<) with effluent meeting the China Grade I-A pollutant discharge standard for municipal WWTPs, indicating that the enhanced Fenton technology is efficient and cost-effective in industrial treatment for textile effluent.</subfield></datafield><datafield tag="650" ind1=" " ind2="4"><subfield code="a">textile wastewater</subfield></datafield><datafield tag="650" ind1=" " ind2="4"><subfield code="a">advanced oxidation process</subfield></datafield><datafield tag="650" ind1=" " ind2="4"><subfield code="a">electrical energy per order</subfield></datafield><datafield tag="650" ind1=" " ind2="4"><subfield code="a">Fenton process</subfield></datafield><datafield tag="653" ind1=" " ind2="0"><subfield code="a">Hydraulic engineering</subfield></datafield><datafield tag="653" ind1=" " ind2="0"><subfield code="a">Water supply for domestic and industrial purposes</subfield></datafield><datafield tag="700" 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Treatment of Textile Wastewater Using Advanced Oxidation Processes—A Critical Review

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